Contactless connector system tolerant of position displacement between transmitter coil and receiver coil and having high transmission efficiency

ABSTRACT

A contactless connector apparatus is provided with a first coil closely opposed to a second coil so as to be electromagnetically coupled thereto. The first coil includes: an inner transmitter coil wound around an axis passing through its center; and an outer transmitter coil wound around the axis and outside the inner coil. One end of the outer transmitter coil is connected to one end of the inner transmitter coil such that, when a current flows through the transmitter coils, a direction of a loop current generated around the axis by a current flowing through the inner transmitter coil is opposite to that of a loop current generated around the axis by a current flowing through the outer transmitter coil. A self-inductance of the outer transmitter coil is larger than that of the inner transmitter coil.

TECHNICAL FIELD

The present disclosure relates to a contactless connector apparatus anda contactless connector system that use inductive coupling betweencoils, and relates to a power transmission apparatus and a powertransmission system that include the contactless connector apparatus orthe contactless connector system.

BACKGROUND ART

In recent years, contactless connector apparatuses and contactlessconnector systems using inductive coupling between coils, and powertransmission apparatuses and power transmission systems provided with acontactless connector apparatus or a contactless connector system havebeen being developed for the purpose of wireless charging of mobileelectronic equipment or EV equipment, such as mobile phones and electriccars. For example, the inventions of Patent Documents 1 to 3 are knownas contactless power transmission systems.

A battery-powered device and a charging cradle of Patent Document 1include: a charging cradle having a power supply coil connected to an ACpower supply; and a battery-powered device to be mounted on the chargingcradle and including an induction coil electromagnetically coupled tothe power supply coil. A built-in battery of the battery-powered deviceis charged with power transmitted from the power supply coil to theinduction coil. The power supply coil includes a planar inner coil, anda planar outer coil disposed outside the inner coil and on the sameplane as the inner coil. The AC power supply to the charging cradleincludes a switching circuit for changing between an inner coil activestate where AC power is supplied to the inner coil and not supplied tothe outer coil, and an inner and outer coil active state where AC poweris supplied to both the inner coil and the outer coil. The AC powersupply changes between the inner coil active state and the inner andouter coil active state by the battery-powered device mounted on thecharging cradle, and transmits power to the induction coil of thebattery-powered device. That is, the battery-powered device and thecharging cradle of Patent Document 1 are characterized by changingbetween two active states to achieve optimal power transmission.

A contactless power transmission apparatus of Patent Document 2 ischaracterized in that the power transmission apparatus transmits powerfrom a primary coil to a secondary coil in a contactless manner throughan gap by using electromagnetic induction between a pair of coilsopposite to each other, and the power transmission apparatus is providedwith a plurality of planar coils at a primary side, and one or moreplanar coils at a secondary side, and the outer diameter of thesecondary coil is smaller than the outer diameter of the primary coils.The contactless power transmission apparatus of Patent Document 2 ischaracterized by selecting an optimal coil from among the plurality ofprimary coils to achieve stable power transmission.

A wireless transmission system of Patent Document 3 is provided with aresonator for wireless power transmission, the resonator including aconductor forming one or more loops and having an inductance, and anetwork of capacitors having a capacitance and a desired electricalparameter and coupled to the conductor. In this case, the network ofcapacitors includes at least one capacitor of a first type having afirst temperature profile as the electrical parameter, and at least onecapacitor of a second type having a second temperature profile as theelectrical parameter.

The principles of such contactless power transmission systems can alsobe applied to information transmission systems provided with acontactless connector apparatus, and to induction heating apparatusessuch as IH cooking apparatuses.

CITATION LIST Patent Documents [Patent Document 1] Japanese PatentLaid-open Publication No. 2011-259534 [Patent Document 2] JapanesePatent Laid-open Publication No. 2009-164293 [Patent Document 3] U.S.Patent Application Publication No. 2010/0181845 SUMMARY OF INVENTIONTechnical Problem

In order to achieve high transmission efficiency in a contactless powertransmission system, it is necessary to accurately align a transmittercoil included in a power transmitter apparatus (e.g., a charger) and areceiver coil included in a power receiver apparatus (e.g., an apparatusto be charged) to oppose to each other, so that a strong electromagneticcoupling occurs between the transmitter coil and the receiver coil.

According to the invention of Patent Document 1, high transmissionefficiency can be achieved when the transmitter coil and the receivercoil are accurately aligned to oppose to each other. However, there is aproblem of a degradation in transmission efficiency when a positiondisplacement occurs. In addition, according to the invention of PatentDocument 2, the stable transmission efficiency is achieved even when aposition displacement occurs. However, there is a problem of an increasein the area of the transmitter coil.

In order to avoid the reduction in transmission efficiency caused by aposition displacement, the invention of Patent Document 3 dynamicallychanges a matching circuit. However, there is a problem that such asolution results in a complicated control.

The same problems are present not only in contactless power transmissionsystems, but also in information transmission systems and inductionheating apparatuses provided with a contactless connector apparatus.

An object of the present disclosure is to solve the above-describedproblems, and to provide a contactless connector apparatus and acontactless connector system that are tolerant of a positiondisplacement between a transmitter coil and a receiver coil and havehigh transmission efficiency, with a simple configuration, and toprovide a power transmission apparatus and a power transmission systemthat include such a contactless connector apparatus.

Solution to Problem

According to a contactless connecter apparatus as an aspect of thepresent disclosure, a contactless connector apparatus is provided with afirst coil closely opposed to a second coil so as to beelectromagnetically coupled to the second coil. The first coil includes:an inner coil wound around an axis passing through a center of the firstcoil; and an outer coil wound around the axis and outside the innercoil. One end of the outer coil and one end of the inner coil areconnected to each other such that, when a current flows through thefirst coil, a direction of a loop current generated around the axis by acurrent flowing through the inner coil is opposite to a direction of aloop current generated around the axis by a current flowing through theouter coil. A self-inductance of the outer coil is larger than aself-inductance of the inner coil.

Advantageous Effects of Invention

According to a contactless connector apparatus, a contactless connectorsystem, a power transmission apparatus, and a power transmission systemof the present disclosure, it is possible to achieve stable powertransmission with sufficiently high transmission efficiency, with a verysimple configuration, even when a position displacement occurs between atransmitter coil and a receiver coil.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view showing a schematic configuration of acontactless connector system according to a first embodiment.

FIG. 2 is a top view showing a schematic configuration of transmittercoils 1 a and 1 b of FIG. 1.

FIG. 3 is a cross-sectional view along line A1-A1′ of FIG. 1.

FIG. 4 is a circuit diagram showing an exemplary equivalent circuit ofthe contactless connector system of FIG. 1.

FIG. 5 is a schematic diagram showing the frequency characteristics oftransmission efficiency for various coupling coefficients k between thetransmitter coils 1 a and 1 b and a receiver coil 2 of FIG. 1.

FIG. 6 is a top view showing transmitter coils 1 a and 1 c of acontactless connector system according to a comparison example of thefirst embodiment

FIG. 7 is a diagram schematically showing changes in mutual inductancewith respect to a position displacement dx of the contactless connectorsystem of FIG. 6.

FIG. 8 is a diagram schematically showing changes in mutual inductancewith respect to a position displacement dx of the contactless connectorsystem of FIG. 1.

FIG. 9 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a first modifiedembodiment of the first embodiment.

FIG. 10 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a second modifiedembodiment of the first embodiment.

FIG. 11 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a third modifiedembodiment of the first embodiment.

FIG. 12 is a perspective view showing a schematic configuration of acontactless connector system according to a fourth modified embodimentof the first embodiment.

FIG. 13 is a perspective view showing a schematic configuration of acontactless connector system according to a fifth modified embodiment ofthe first embodiment.

FIG. 14 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a second embodiment.

FIG. 15 is a top view showing a magnetic substrate 13 of FIG. 14.

FIG. 16 is a cross-sectional view along line A2-A2′ of FIG. 14.

FIG. 17 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a third embodiment.

FIG. 18 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a modified embodiment ofthe third embodiment.

FIG. 19 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a fourth embodiment.

FIG. 20 is a cross-sectional view along line A3-A3′ of FIG. 19.

FIG. 21 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a first modified embodimentof the fourth embodiment.

FIG. 22 is a cross-sectional view along line A4-A4′ of FIG. 21.

FIG. 23 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a second modifiedembodiment of the fourth embodiment.

FIG. 24 is a cross-sectional view along line A5-A5′ of FIG. 23.

FIG. 25 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a third modified embodimentof the fourth embodiment.

FIG. 26 is a cross-sectional view along line A6-A6′ of FIG. 25.

FIG. 27 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a fourth modifiedembodiment of the fourth embodiment.

FIG. 28 is a cross-sectional view along line A7-A7′ of FIG. 27.

FIG. 29 is a cross-sectional view showing a schematic configuration of atransmitter contactless connector apparatus according to a fifthmodified embodiment of the fourth embodiment.

FIG. 30 is a cross-sectional view showing a schematic configuration of atransmitter contactless connector apparatus according to a sixthmodified embodiment of the fourth embodiment.

FIG. 31 is a diagram showing a part of a transmitter coil of acontactless connector system according to a fifth embodiment.

FIG. 32 is a diagram showing a part of a transmitter coil of acontactless connector system according to a sixth embodiment.

FIG. 33 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a seventhembodiment.

FIG. 34 is a schematic diagram showing an array of transmitter coils ofa contactless connector system according to an eighth embodiment.

FIG. 35 is a schematic diagram showing an array of transmitter coils ofa contactless connector system according to a comparison example of theeighth embodiment.

FIG. 36 is a block diagram showing a schematic configuration of a powertransmission system according to a ninth embodiment.

FIG. 37 is a perspective view showing a model of transmitter coils andreceiver coils of a contactless connector system according to a firstimplementation example.

FIG. 38 is a graph showing the mutual inductances between coils of acontactless connector system according to a first comparison example.

FIG. 39 is a graph showing the mutual inductances between the coils ofthe contactless connector system according to the first implementationexample.

FIG. 40 is a graph showing the sums of the mutual inductances shown inFIGS. 38 and 39.

FIG. 41 is a cross-sectional view showing a schematic configuration of acontactless connector system according to a second implementationexample.

FIG. 42 is a graph showing the mutual inductances of the contactlessconnector systems according to the second implementation example and asecond comparison example.

FIG. 43 is a graph showing the transmission efficiency of thecontactless connector system according to the second comparison example.

FIG. 44 is a graph showing the transmission efficiency of thecontactless connector system according to the second implementationexample.

FIG. 45 is a cross-sectional view showing a schematic configuration of acontactless connector system of a third implementation example.

FIG. 46 is a graph showing changes in mutual inductance with respect toa position displacement dx, and with respect to the number of turns ofinner coils, of the contactless connector system of FIG. 45.

FIG. 47 is a graph showing normalized power transmittable areas ofcontactless connector systems according to a fourth implementationexample and a third comparison example.

FIG. 48 is a graph showing an expansion ratio of the power transmittableareas of the contactless connector systems according to the fourthimplementation example and the third comparison example.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present disclosure will be described below withreference to the drawings. Note that like components are denoted by thesame reference signs.

First Embodiment

FIG. 1 is a perspective view showing a schematic configuration of acontactless connector system according to a first embodiment. FIG. 2 isa top view showing a schematic configuration of transmitter coils 1 aand 1 b of FIG. 1. FIG. 3 is a cross-sectional view along line A1-A1′ ofFIG. 1. The contactless connector system of the present embodimentincludes a transmitter contactless connector apparatus including thetransmitter coils 1 a and 1 b; and a receiver contactless connectorapparatus including a receiver coil 2. The contactless connector systemtransmits signals, power, or the like, using electromagnetic couplingbetween the transmitter coils 1 a, 1 b and the receiver coil 2.

Referring to FIG. 1, “11” denotes a housing of the transmittercontactless connector apparatus, and “12” denotes a housing of thereceiver contactless connector apparatus. In FIG. 1, etc., a powersupply, a transmitter circuit, a receiver circuit, etc., which arerequired to transmit signals or power, are omitted for ease ofillustration.

Referring to FIGS. 1 to 3, the transmitter coils 1 a and 1 b include: aninner transmitter coil 1 b wound around an axis passing through a centerO1 of the transmitter coils 1 a and 1 b; and an outer transmitter coil 1a wound around the axis and outside the inner transmitter coil. Thereceiver coil 2 is wound around an axis passing through a center O2 ofthe receiver coil 2. For example, the transmitter coils 1 a and 1 b areprovided on a first plane (the top surface of the housing 11substantially parallel to the XY-plane), and the receiver coil 2 isprovided on a second plane (the bottom surface of the housing 12substantially parallel to the XY-plane) closely opposed to the firstplane. The transmitter coils 1 a, 1 b and the receiver coil 2 areclosely opposed to each other, and thus, electromagnetically coupled toeach other. The transmitter coils include the outer transmitter coil 1 awound clockwise around the axis passing through the center O1 of thetransmitter coils (when viewed from the top in FIG. 1); and the innertransmitter coil 1 b wound counterclockwise around the axis (when viewedfrom the top in FIG. 1) and inside the outer transmitter coil 1 a. Thatis, the direction in which the inner transmitter coil 1 b is woundaround the axis is opposite to the direction in which the outertransmitter coil 1 a is wound around the axis. The outer transmittercoil 1 a has terminals P1 and P2 at its both ends, and the innertransmitter coil 1 b has terminals P3 and P4 at its both ends. Theterminals P2 and P3 are connected to each other by a connecting element3 such that, when a current flows through the transmitter coils 1 a and1 b, the direction of a loop current generated around the axis by thecurrent flowing through the inner transmitter coil 1 b is opposite tothe direction of a loop current generated around the axis by the currentflowing through the outer transmitter coil 1 a. In addition, theterminals P1 and P4 are connected to a transmitter circuit (not shown).In addition, the receiver coil 2 is wound clockwise or counterclockwisearound the axis passing through the center O2 of the receiver coil 2.The receiver coil 2 has terminals P5 and P6 at its both ends. Theterminals P5 and P6 are connected to a receiver circuit (not shown).

The transmitter coils 1 a and 1 b are configured such that theself-inductance of the outer transmitter coil 1 a is larger than theself-inductance of the inner transmitter coil 1 b. The ratio of theself-inductance of the inner transmitter coil 1 b to the self-inductanceof the outer transmitter coil 1 a is, for example, greater than 0 andless than 0.45, as will be described with reference to FIGS. 47 and 48.

For example, the transmitter coils 1 a and 1 b can be configured from,but not limited thereto, the outer transmitter coil 1 a with 10 turns,and the inner transmitter coil 1 b with 5 turns, the transmitter coils 1a and 1 b having radial lengths equal to each other. Both the number ofturns and the radial length may affect the characteristics of thetransmitter coils 1 a and 1 b. However, the inventors have found thatthe radial length is dominant. According to the experiments conducted bythe inventors, power transmission of 5 W was achieved through thetransmitter coils and the receiver coil with diameters of 3 to 4 cm, bysupplying an alternating current of 100 to 200 kHz to the transmittercoils 1 a and 1 b.

The operating principle of the contactless connector system of thepresent embodiment will be described below.

A case is considered in which, as shown in FIG. 3, the transmitter coils1 a, 1 b and the receiver coil 2 are separated by “dz” in theZ-direction, and the center O1 of the transmitter coils 1 a and 1 b andthe center O2 of the receiver coil 2 are displaced from each other by“dx” in the X-direction.

In general, in a conventional contactless connector system, when acurrent flows through a transmitter coil, the current generates anelectromagnetic field around the transmitter coil, the electromagneticfield induces electromotive force in a receiver coil, and then, aninduced current flows through the receiver coil. In other words, thetransmitter coil and the receiver coil are electromagnetically coupledto each other. The following coupling coefficient k is used as an indexfor evaluating the strength of the coupling.

k=M/(√L1×√L2)

“M” denotes the mutual inductance between the transmitter coil and thereceiver coil, “L1” denotes the self-inductance of the transmitter coil,and “L2” denotes the self-inductance of the receiver coil. The couplingcoefficient k ranges: 0≦|k|≦1.

FIG. 4 is a circuit diagram showing an exemplary equivalent circuit ofthe contactless connector system of FIG. 1. Q is a signal source, Z01 isthe internal impedance of the transmitter circuit, Z02 is the loadimpedance of the receiver circuit and a load, R1 and R2 are resistancecomponents, and C1 and C2 are matching capacitors. When the contactlessconnector system operates at an angular frequency ω, a parameter S21indicative of transmission efficiency can be expressed using theself-inductances L1 and L2 and the mutual inductance M of thetransmitter coils 1 a, 1 b and the receiver coil 2, as follows.

          [Mathematical  Expression  1]${S\; 21} = \frac{j \cdot 2 \cdot \omega \cdot M \cdot \sqrt{{{Re}\left\lbrack {Z\; 01} \right\rbrack} \cdot {{Re}\left\lbrack {Z\; 02} \right\rbrack}}}{\begin{matrix}{\left( {\left( {{R\; 1} + {Z\; 01}} \right) + {j \cdot \left( {{{\omega \cdot L}\; 1} - \frac{1}{{\omega \cdot C}\; 1}} \right)}} \right) \cdot} \\{\left( {\left( {{R\; 2} + {Z\; 02}} \right) + {j \cdot \left( {{{\omega \cdot L}\; 2} - \frac{1}{{\omega \cdot C}\; 2}} \right)}} \right) + \left( {\omega \cdot M} \right)^{2}}\end{matrix}}$

It is noted that the equivalent circuit of FIG. 4 and the equation ofthe parameter S21 are mere examples, and the equivalent circuit andtransmission efficiency of the contactless connector system may beexpressed using any other appropriate model. For example, there issubstantially no internal impedance Z01 depending on the configurationof the transmitter circuit. The following description of the operatingprinciple also applies to contactless connector systems corresponding toequivalent circuits different than that of FIG. 4.

When the transmitter coils 1 a, 1 b and the receiver coil 2 areelectromagnetically strongly coupled to each other, |k|≠1. As thedistance dx or dz increases, the value of |k| decreases. When thetransmitter coils 1 a, 1 b and the receiver coil 2 are notelectromagnetically coupled to each other, |k|=0.

FIG. 5 is a schematic diagram showing the frequency characteristics oftransmission efficiency for various coupling coefficients k between thetransmitter coils 1 a, 1 b and the receiver coil 2 of FIG. 1. It isassumed that in FIG. 5, the Q factor is constant. According to FIG. 5,it can be seen that the transmission efficiency bandwidth variesdepending on the coupling coefficient k. Normally, when the transmittercoils 1 a, 1 b and the receiver coil 2 are aligned with each other (whenthe centers O1 and O2 in FIG. 3 coincide with each other), a strongelectromagnetic coupling occurs between the transmitter coils 1 a, 1 band the receiver coil 2, and the transmission efficiency has two peaksand ranges over narrow bands. Thus, the contactless connector system cannot achieve wideband operation. Therefore, in order to achieve widebandoperation, it is necessary to decrease the coupling coefficient k, i.e.,decrease the mutual inductance M, when the transmitter coils 1 and thereceiver coil 2 are close to each other. On the other hand, when thetransmitter coils 1 a, 1 b and the receiver coil 2 are displaced fromeach other, the electromagnetic coupling between the transmitter coils 1a, 1 b and the receiver coil 2 decreases, and the number of peaks of thetransmission efficiency changes from two to one. However, as thedistance between the transmitter coils 1 a, 1 b and the receiver coil 2increases, the transmission efficiency decreases. Therefore, in thiscase, it is necessary to instead increase the coupling coefficient k,i.e., increase the mutual inductance M. In short, in order to preventchanges in transmission efficiency caused by a position displacementbetween the transmitter coils 1 a, 1 b and the receiver coil 2, it isessential to decrease the mutual inductance M when the transmitter coils1 a, 1 b and the receiver coil 2 are aligned with each other, andsuppress the decrease in the mutual inductance M when they are displacedfrom each other.

FIG. 6 is a top view showing transmitter coils 1 a and 1 c of acontactless connector system according to a comparison example of thefirst embodiment. The transmitter coils 1 a and 1 c of FIG. 6 are shownto compare a transmitter coil of a conventional contactless connectorsystem with the contactless connector system of FIG. 1. The contactlessconnector system of FIG. 1 is provided with the inner transmitter coil 1b wound counterclockwise. On the other hand, the contactless connectorsystem of FIG. 6 is provided with the inner transmitter coil 1 c woundclockwise. That is, the direction in which the inner transmitter coil 1c is wound around an axis passing through a center O1 is the same as thedirection in which the outer transmitter coil 1 a is wound around theaxis. Terminals P2 and P3 are connected to each other by a connectingelement 3A such that, when a current flows through the transmitter coils1 a and 1 c of FIG. 6, the direction of a loop current generated aroundthe axis by the current flowing through the inner transmitter coil 1 cis the same as the direction of a loop current generated around the axisby the current flowing through the outer transmitter coil 1 a.

FIG. 7 is a diagram schematically showing changes in mutual inductancewith respect to a position displacement dx of the contactless connectorsystem of FIG. 6. The position displacement dx is defined as shown inFIG. 3. Referring to FIG. 7, “1 a” indicates the mutual inductancebetween the outer transmitter coil 1 a of FIG. 6 and a receiver coil(not shown) which is the same as the receiver coil 2 of FIG. 1, “1 c”indicates the mutual inductance between the inner transmitter coil 1 cof FIG. 6 and the receiver coil, and “1 a+1 c” indicates the mutualinductance between both the transmitter coils 1 a, 1 c and the receivercoil. The mutual inductance “1 c” is large for zero or a small positiondisplacement dx, but decreases as the position displacement dxincreases, and becomes negative at a certain position. Therefore, themutual inductance “1 a+1 c” varies over a wide range so as to be largefor zero or a small position displacement dx, but small for a largeposition displacement dx.

FIG. 8 is a diagram schematically showing changes in mutual inductancewith respect to a position displacement dx of the contactless connectorsystem of FIG. 1. Referring to FIG. 8, “1 a” indicates the mutualinductance between the outer transmitter coil 1 a and the receiver coil2, “1 b” indicates the mutual inductance between the inner transmittercoil 1 b and the receiver coil 2, and “1 a+1 b” indicates the mutualinductance between both the transmitter coils 1 a, 1 b and the receivercoil 2. As described above, the transmitter coils 1 a and 1 b areconfigured such that, when a current flows through the transmitter coils1 a and 1 b, the direction of a loop current generated around the axispassing through the center O1 by the current flowing through the innertransmitter coil 1 b is opposite to the direction of a loop currentgenerated around the axis by the current flowing through the outertransmitter coil 1 a. The contactless connector system of the presentembodiment is further configured such that the mutual inductance betweenthe inner transmitter coil 1 b and the receiver coil 2 is negative forzero and a small position displacement dx, and the mutual inductancebetween the inner transmitter coil 1 b and the receiver coil 2 ispositive for a position displacement dx larger than a predeterminedvalue. By doing so, there is an effect of decreasing the mutualinductance between both the transmitter coils 1 a, 1 b and the receivercoil 2 for zero and a small position displacement dx, to decreaseelectromagnetic coupling. In addition, as compared to the case of theconventional contactless connector system (FIG. 7), there is an effectof suppressing a decrease in the mutual inductance between both thetransmitter coils 1 a, 1 b and the receiver coil 2 for a large positiondisplacement dx. As a result, it is possible to achieve stable powertransmission with sufficiently high transmission efficiency, regardlessof the positional relationship between the transmitter coils 1 a, 1 band the receiver coil 2. Further, it is conventionally necessary toincrease transmission power in order to deal with a reduction intransmission efficiency, thus resulting in increased heat generation. Onthe other hand, the transmission efficiency does not decrease in thecontactless connector system of the present embodiment, and thus, thereis an effect of preventing heat generation.

The coupling coefficient k will be further described with reference toFIG. 5. As described above, the transmission efficiency has two peaksand ranges over narrow bands when a strong electromagnetic couplingoccurs between the transmitter coils 1 a, 1 b and the receiver coil 2.However, when gradually decreasing the coupling coefficient k, thefrequency interval between two peaks of the transmission efficiencygradually decreases, and the local minimum of the transmissionefficiency between the two peaks gradually increases. A powertransmission system has its maximum bandwidth, when the frequencyinterval becomes substantially 0, in other words, when the differencebetween the two peaks and the local minimum therebetween of thetransmission efficiency is small (e.g., 5 to 10%). A value of thecoupling coefficient k is determined so as to satisfy this condition.The parameters of the power transmission system (the numbers of turns,radial lengths, etc., of the transmitter coils 1 a, 1 b and the receivercoil 2) are determined so as to obtain the determined value of thecoupling coefficient k.

Since the contactless connector system of the present embodiment isconfigured as described above, it is possible to achieve stable powertransmission with sufficiently high transmission efficiency, with a verysimple configuration, even when a position displacement occurs betweenthe transmitter coils and the receiver coil.

FIG. 9 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a first modifiedembodiment of the first embodiment. An outer transmitter coil 1 a and aninner transmitter coil 1 b may be connected to each other in a differentmanner from that of FIG. 1, provided that, when a current flows throughthe transmitter coils 1 a and 1 b, the direction of a loop currentgenerated around an axis passing through a center O1 by the currentflowing through the inner transmitter coil 1 b is opposite to thedirection of a loop current generated around the axis by the currentflowing through the outer transmitter coil 1 a. Referring to FIG. 9,terminals P1 and P4 are connected to each other by a connecting element3B. In addition, terminals P2 and P3 are connected to a transmittercircuit (not shown).

FIG. 10 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a second modifiedembodiment of the first embodiment. FIG. 11 is a top view showing aschematic configuration of transmitter coils of a contactless connectorsystem according to a third modified embodiment of the first embodiment.Each of the contactless connector systems of FIGS. 10 and 11 is providedwith an inner transmitter coil 1 c wound clockwise in a manner similarto that of the contactless connector system of FIG. 6. In the case ofFIG. 10, terminals P2 and P4 are connected to each other by a connectingelement 3C such that, when a current flows through transmitter coils 1 aand 1 c, the direction of a loop current generated around an axispassing through a center O1 by the current flowing through the innertransmitter coil 1 c is opposite to the direction of a loop currentgenerated around the axis by the current flowing through the outertransmitter coil 1 a. In this case, terminals P1 and P3 are connected toa transmitter circuit (not shown). In the case of FIG. 11, similarly,terminals P1 and P3 are connected to each other by a connecting element3D, and terminals P2 and P4 are connected to a transmitter circuit (notshown).

In a manner similar to that of the contactless connector system of FIG.1, the contactless connector systems of FIGS. 9 to 11 can also achievestable power transmission with sufficiently high transmissionefficiency, with a very simple configuration, even when a positiondisplacement occurs between the transmitter coils and the receiver coil.

FIG. 12 is a perspective view showing a schematic configuration of acontactless connector system according to a fourth modified embodimentof the first embodiment. The contactless connector system of the presentmodified embodiment includes: a transmitter contactless connectorapparatus including a transmitter coil 1; and a receiver contactlessconnector apparatus including receiver coils 2 a and 2 b. In thecontactless connector system of the present modified embodiment, thereceiver coils 2 a and 2 b are configured such that, when a currentflows through the receiver coils 2 a and 2 b instead of through thetransmitter coil 1, the direction of a loop current generated around anaxis passing through the center of the inner receiver coil 2 b by thecurrent flowing through the inner receiver coil 2 b is opposite to thedirection of a loop current generated around the axis by the currentflowing through the outer receiver coil 2 a.

Referring to FIG. 12, the transmitter coil 1 is wound around an axispassing through a center of the transmitter coil 1. The receiver coils 2include the inner receiver coil 2 b wound around the axis passingthrough a center of the receiver coils 2; and the outer receiver coil 2a wound around the axis and outside the inner receiver coil. Forexample, the transmitter coil 1 is provided on a first plane (the topsurface of a housing 11 substantially parallel to the XY-plane), and thereceiver coils 2 a and 2 b are provided on a second plane (the bottomsurface of a housing 12 substantially parallel to the XY-plane) closelyopposed to the first plane. The transmitter coil 1 and the receivercoils 2 a, 2 b are closely opposed to each other, and thus,electromagnetically coupled to each other. The transmitter coil 1 iswound clockwise or counterclockwise around the axis passing through thecenter of the transmitter coil 1. The transmitter coil 1 has terminalsP7 and P8 at its both ends. The terminals P7 and P8 are connected to atransmitter circuit (not shown). In addition, the receiver coils includethe outer receiver coil 2 a wound clockwise around the axis passingthrough the center of the receiver coils 2; and the inner receiver coil2 b wound counterclockwise around the axis and inside the outer receivercoil 2 a. The outer receiver coil 2 a has terminals P9 and P10 at itsboth ends, and the inner receiver coil 2 b has terminals P11 and P12 atits both ends. The terminals P10 and P11 are connected to each other bya connecting element 4 such that, when a current flows through thereceiver coils 2 a and 2 b, the direction of a loop current generatedaround the axis passing through the center of the inner receiver coil 2b by the current flowing through the inner receiver coil 2 b is oppositeto the direction of a loop current generated around the axis by thecurrent flowing through the outer receiver coil 2 a. In addition, theterminals P9 and P12 are connected to a receiver circuit (not shown).

FIG. 13 is a perspective view showing a schematic configuration of acontactless connector system according to a fifth modified embodiment ofthe first embodiment. As shown in FIG. 13, the transmitter contactlessconnector apparatus of FIG. 1 may be combined with the receivercontactless connector apparatus of FIG. 12.

In a manner similar to that of the contactless connector system of FIG.1, the contactless connector systems of FIGS. 12 and 13 can also achievestable power transmission with sufficiently high transmissionefficiency, with a very simple configuration, even when a positiondisplacement occurs between the transmitter coils and the receivercoils.

Second Embodiment

FIG. 14 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a second embodiment. FIG.15 is a top view showing a magnetic substrate 13 of FIG. 14. FIG. 16 isa cross-sectional view along line A2-A2′ of FIG. 14. The transmittercontactless connector apparatus is provided with: conducting wires 5 and6 connected to terminals P1 and P4, respectively; and a magneticsubstrate 13 provided on one side with respect to transmitter coils 1 aand 1 b, the one side being opposite to a side where a receiver coil isprovided close to the transmitter coils 1 a and 1 b. The conductingwires 5 and 6 are connected to a transmitter circuit (not shown). Themagnetic substrate 13 is, for example, ferrite, and serves as a shieldfor the transmitter circuit. As shown in FIG. 15, the magnetic substrate13 may further have grooves G1 and G2 into which at least a part of thetransmitter coils 1 a and 1 b and the conducting wires 5 and 6 isinserted. In the case shown in FIGS. 14 to 16, since the conducting wire6 is routed under the transmitter coils 1 a and 1 b, the conducting wire6 is inserted into the groove G1. Normally, the thickness of thetransmitter coils increases due to the conducting wire 6 extending fromthe inner transmitter coil 1 b to a portion external to the outertransmitter coil 1 a. However, by inserting the conducting wire 6 intothe groove G1, there is an effect of removing unnecessary protrusionsfrom the contactless connector apparatus. In addition, when an outertransmitter coil 1 a and an inner transmitter coil 1 b are configured byfolding a single conducting wire as shown in FIG. 31, the thickness ofthe transmitter coils increases at the fold of the conducting wire.However, in this case, by inserting the fold of the conducting wire intothe groove G2, there is an effect of removing unnecessary protrusionsfrom the contactless connector apparatus.

The groove G2 for the fold of the conducting wire may be provided asnecessary.

Third Embodiment

FIG. 17 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a third embodiment. Thetransmitter contactless connector apparatus is provided with conductingwires 5 and 6A connected to terminals P1 and P4, respectively. Theterminal P4 is close to an axis passing through a center O1, and theterminal P1 is remote from the axis. The conducting wire 6A connected tothe terminal P4 of an inner transmitter coil 1 b is wound clockwisearound the axis so as to gradually increase a distance from the axis.When the magnetic substrate 13 of FIG. 14 is very thin not enough toprovide a groove G1 into which a conducting wire 6 is completelyinserted, the conducting wire 6A wound in the manner as shown in FIG. 17may be used. Thus, it is possible to remove unnecessary protrusions fromthe contactless connector apparatus. In addition, there is an effect offurther improving tolerance to a position displacement by virtue of themutual inductance between the wound conducting wire 6A and a receivercoil. When the conducting wire 6A has an insulating cover, theconducting wire 6A may be in contact with the inner transmitter coil 1 band an outer transmitter coil 1 a.

FIG. 18 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a modified embodiment ofthe third embodiment. The transmitter contactless connector apparatus isprovided with conducting wires 5 and 6B connected to terminals P1 andP4, respectively. The conducting wire 6B connected to the terminal P4 ofan inner transmitter coil 1 b is wound counterclockwise around an axispassing through a center O1, so as to gradually increases a distancefrom the axis. The contactless connector apparatus of FIG. 18 also hasthe same effects as those obtained by the contactless connectorapparatus of FIG. 17. When the conducting wire 6B has an insulatingcover, the conducting wire 6B may be in contact with the innertransmitter coil 1 b and an outer transmitter coil 1 a.

Fourth Embodiment

FIG. 19 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a fourth embodiment. FIG.20 is a cross-sectional view along line A3-A3′ of FIG. 19. Transmittercoils 1 a and 1 b of FIG. 19 are the same as the transmitter coils 1 aand 1 b of FIG. 1. Each of the outer transmitter coil 1 a and the innertransmitter coil 1 b may be formed (patterned) on at least one surfaceof a dielectric substrate 14 of a printed circuit board using a circuitpatterning method. Referring to FIG. 19, the outer transmitter coil 1 a,the inner transmitter coil 1 b, and a connecting element 3 are patternedon the top surface of the dielectric substrate 14. The contactlessconnector apparatus is provided with conducting wires 5 and 6 connectedto terminals P1 and P4, respectively. The conducting wire 5 is patternedon the top surface of the dielectric substrate 14. The conducting wire 6is provided with: a conductor patterned on the bottom surface of thedielectric substrate 14; and a via conductor 15 going through thedielectric substrate 14.

FIG. 21 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a first modified embodimentof the fourth embodiment. FIG. 22 is a cross-sectional view along lineA4-A4′ of FIG. 21. Referring to FIG. 21, an outer transmitter coil 1 aand a connecting element 3 are patterned on the top surface of adielectric substrate 14, and an inner transmitter coil 1 b is patternedon the bottom surface of the dielectric substrate 14. A conducting wire5 is patterned on the top surface of the dielectric substrate 14. Thecontactless connector apparatus is further provided with a via conductor15A going through the dielectric substrate 14 to connect the connectingelement 3 to the inner transmitter coil 1 b.

FIG. 23 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a second modifiedembodiment of the fourth embodiment. FIG. 24 is a cross-sectional viewalong line A5-A5′ of FIG. 23. As shown in FIG. 23, transmitter coils 1 aand 1 b may be partially patterned on the top surface of a dielectricsubstrate 14, and partially patterned on the bottom surface of thedielectric substrate 14. The portions patterned on the top surface ofthe dielectric substrate 14 and the portions patterned on the bottomsurface of the dielectric substrate 14 are connected to each otherthrough via conductors 15D going through the dielectric substrate 14.According to the configuration of FIG. 23, the direction in which thetransmitter coils are electromagnetically coupled to a receiver coil canbe tilted from a vertical direction (Z-direction).

FIG. 25 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a third modified embodimentof the fourth embodiment. FIG. 26 is a cross-sectional view along lineA6-A6′ of FIG. 25. Transmitter coils 1 a and 1 c of FIG. 25 are the sameas the transmitter coils 1 a and 1 c of FIG. 10. The contactlessconnector apparatus is provided with conducting wires 5 and 6C connectedto terminals P1 and P3, respectively. The conducting wire 5 includes: aconductor patterned on the top surface of a dielectric substrate 14; anda via conductor 15B1 going through the dielectric substrate 14. Theconducting wire 6C includes: a conductor patterned on the bottom surfaceof the dielectric substrate 14; and via conductors 15B2 and 15B3 goingthrough the dielectric substrate 14.

FIG. 27 is a top view showing a schematic configuration of a transmittercontactless connector apparatus according to a fourth modifiedembodiment of the fourth embodiment. FIG. 28 is a cross-sectional viewalong line A7-A7′ of FIG. 27. Referring to FIG. 27, an outer transmittercoil 1 a is patterned on the top surface of a dielectric substrate 14,and an inner transmitter coil 1 c is patterned on the bottom surface ofthe dielectric substrate 14. A connecting element 3C includes: aconductor patterned on the top surface of the dielectric substrate 14;and a via conductor 15C going through the dielectric substrate 14. Aconducting wire 5 is patterned on the top surface of the dielectricsubstrate 14. A conducting wire 6C is patterned on the bottom surface ofthe dielectric substrate 14.

FIG. 29 is a cross-sectional view showing a schematic configuration of atransmitter contactless connector apparatus according to a fifthmodified embodiment of the fourth embodiment. FIG. 30 is across-sectional view showing a schematic configuration of a transmittercontactless connector apparatus according to a sixth modified embodimentof the fourth embodiment. As shown in FIGS. 29 and 30, transmitter coilsmay be patterned on both surfaces of a dielectric substrate 14. Thecontactless connector apparatus of FIG. 29 is provided with: outertransmitter coils 1 a and 1 aa patterned on both surfaces of thedielectric substrate 14; and inner transmitter coils 1 b and 1 bapatterned on both surfaces of the dielectric substrate 14. Thecontactless connector apparatus of FIG. 30 is provided with: outertransmitter coils 1 ab and 1 ac patterned on both surfaces of thedielectric substrate 14; and inner transmitter coils 1 bb and 1 bcpatterned on both surfaces of the dielectric substrate 14. The number ofturns of the transmitter coils may be equal between the top and bottomsurfaces of the dielectric substrate 14 as shown in FIG. 29, or may beunequal between the top and bottom surfaces of the dielectric substrate14 as shown in FIG. 30 for fine adjustment of the characteristics of thecontactless connector apparatus.

According to the contactless connector apparatuses of FIGS. 19 to 30,there is an effect of reducing thickness by integrally forming the outertransmitter coil 1 a and the inner transmitter coil 1 b on thedielectric substrate 14.

Fifth Embodiment

FIG. 31 is a diagram showing a part of a transmitter coil of acontactless connector system according to a fifth embodiment. It is notlimited to provide the outer transmitter coil 1 a, the inner transmittercoil 1 b, and the connecting element 3 of FIG. 1 as separate conductingwires. The outer transmitter coil 1 a, the inner transmitter coil 1 b,and the connecting element 3 may be configured by folding a singleconducting wire. Thus, it is simplify the configuration of thetransmitter coils.

On the other hand, when the outer transmitter coil 1 a, the innertransmitter coil 1 b, and the connecting element 3 are configured usingseparate conducting wires, patterned conductors, solder, etc., orconfigured using different materials, there is an effect of reducing theoverall cost of the contactless connector apparatus, for example, byusing a low-resistance material only for the outer transmitter coil 1 aalong a long looped path.

Sixth Embodiment

FIG. 32 is a diagram showing a part of a transmitter coil of acontactless connector system according to a sixth embodiment. A terminalP2 of an outer transmitter coil 1 a and a terminal P3 of an innertransmitter coil 1 b may be connected to each other through an impedanceelement 21, which is a passive element having a predetermined impedance.The impedance element 21 is one of a resistor, a capacitor, an inductor,and a current inverter circuit.

For example, when a resistor is used as the impedance element 21, thereis an effect of decreasing the Q factor and increasing the bandwidth.Further, for example, a resistor of 1Ω or less may be used to reducedistortion of waveform and improve noise immunity.

In addition, when a capacitor is used as the impedance element 21, thereis an effect of reducing the area of a matching circuit to be providedexternal to the transmitter coils 1 a and 1 b. In addition, acombination of a capacitor provided as the impedance element 21 and acapacitor provided external to the transmitter coils 1 a and 1 b may beused. In addition, for example, a capacitor of 100 to 300 nF may be usedto adjust the resonance frequency.

In addition, when an inductor is used as the impedance element 21, thereis an effect of increasing the total self-inductance of the transmittercoils 1 a and 1 b, the total self-inductance having decreased by windingthe inner transmitter coil 1 b and the outer transmitter coil 1 a inopposite directions to each other. In addition, an inductor may be usedto increase the electrical lengths of the transmitter coils 1 a and 1 b.

In addition, a current inverter circuit (e.g., a 1:1 transformer, etc.)may be used as the impedance element 21 to invert the polarity ofcurrents flowing through the transmitter coils 1 a and 1 b.

By using a combination of these passive elements as the impedanceelement 21, there is an effect of adjusting the impedances of thetransmitter coils 1 a and 1 b so as to further improve transmissionefficiency, while reducing the area of the matching circuit.

Seventh Embodiment

FIG. 33 is a top view showing a schematic configuration of transmittercoils of a contactless connector system according to a seventhembodiment. A transmitter contactless connector apparatus may beprovided with an additional transmitter coil 1 d around an axis passingthrough a center O1 and further inside an inner transmitter coil 1 bsuch that, when a current flows through the transmitter coils, a loopcurrent flows around the axis in an opposite direction to that of a loopcurrent generated around the axis by the current flowing through theinner transmitter coil 1 b. The additional transmitter coil 1 d iswound, for example, clockwise. The additional transmitter coil 1 d hasterminals P13 and P14 at its both ends. A terminal P4 and the terminalP13 are connected to each other by a connecting element 7 such that,when a current flows through the transmitter coils, the direction of aloop current generated around the axis by the current flowing throughthe additional transmitter coil 1 d is opposite to the direction of aloop current generated around the axis by the current flowing throughthe inner transmitter coil 1 b. According to this configurationincluding the additional transmitter coil 1 d, it is possible to finelyadjust the characteristics of the contactless connector apparatus.

According to the configuration of FIG. 33, the direction in which theadditional transmitter coil 1 d is wound around the axis passing throughthe center O1 is opposite to the direction in which the innertransmitter coil 1 b is wound around the axis. However, these directionsmay be the same. In this case, the transmitter coils 1 a, 1 b, and 1 dare configured such that, when a current flows through the transmittercoils, the direction of a loop current generated around the axis by thecurrent flowing through the additional transmitter coil 1 d is oppositeto that of a loop current generated around the axis by the currentflowing through the inner transmitter coil 1 b. In addition, similarly,the contactless connector apparatus may be provided with a transmittercoil further inside the additional transmitter coil 1 d.

Eighth Embodiment

FIG. 34 is a schematic diagram showing an array of transmitter coils ofa contactless connector system according to an eighth embodiment. FIG.35 is a schematic diagram showing an array of transmitter coils of acontactless connector system according to a comparison example of theeighth embodiment. The array of FIG. 34 includes a plurality oftransmitter coils 31-1 to 31-3 disposed regularly. The transmitter coils31-1 to 31-3 are wound around a plurality of parallel axes located atregular intervals D11, respectively. Each of the transmitter coils 31-1to 31-3 is configured in a manner similar to the transmitter coils ofFIG. 1, etc. In addition, the array of FIG. 35 includes a plurality oftransmitter coils 32-1 to 32-3, each configured in a manner similar tothat of FIG. 6 (i.e., without the inner transmitter coil 1 b of FIG. 1).In FIGS. 34 and 35, thick dashed lines above the transmitter coilsindicate the mutual inductance between the transmitter coils andreceiver coils (not shown), and solid lines above the thick dashed linesindicate the combined mutual inductance of the transmitter coils. Thearray of FIG. 35 has a problem that even when a plurality of transmittercoils are disposed, if a receiver coil is located between adjacenttransmitter coils, then the mutual inductance decreases, and thus thetransmission efficiency decreases. On the other hand, in the array ofFIG. 34, even when a position displacement occurs between a transmittercoil and a receiver coil, it is possible to achieve stable powertransmission with sufficiently high transmission efficiency, with a verysimple configuration. Thus, there is an effect of achievingposition-independent stable power transmission over the entire array.FIG. 34 shows the three transmitter coils 31-1 to 31-3 disposed along astraight line. However, four or more transmitter coils may be disposedor a plurality of transmitter coils may be disposed two-dimensionally.

Ninth Embodiment

FIG. 36 is a block diagram showing a schematic configuration of a powertransmission system according to a ninth embodiment. It is possible toconfigure a power transmission system including any of the contactlessconnector systems described above. The power transmission systemincludes: a transmitter power transmission apparatus provided with atransmitter contactless connector apparatus; and a receiver powertransmission apparatus provided with a receiver contactless connectorapparatus. Referring to FIG. 36, in the transmitter power transmissionapparatus, transmitter coils 1 a and 1 b (FIG. 1) are connected to apower transmitter circuit 102, and the power transmitter circuit 102 isconnected to a power supply 101. In the receiver power transmissionapparatus, a receiver coil 2 (FIG. 1) is connected to a power receivercircuit 103, and the power receiver circuit 103 is connected to a load104 (e.g., a battery, etc.). When power is supplied to the transmittercoils 1 a and 1 b, a current flows through the transmitter coils 1, thecurrent generates an electromagnetic field around the transmitter coils1 a and 1 b, the electromagnetic field induces electromotive force inthe receiver coil 2, and then, an induced current flows through thereceiver coil 2. By supplying the induced current to the load 104, it ispossible to achieve power transmission between the transmitter coils 1a, 1 b and the receiver coil 2.

According to the power transmission system of the present embodiment, itis possible to achieve stable power transmission with sufficiently hightransmission efficiency, with a very simple configuration, even when aposition displacement occurs between the transmitter coils 1 a, 1 b andthe receiver coil 2.

Using the above-described contactless connector systems, signals may betransmitted instead of transmitting power.

It is possible to configure an induction heating apparatus based on theprinciple of the above-described power transmission systems. In theinduction heating apparatus, the transmitter coils of FIG. 1 serving asinduction heating coils are connected to a cooking circuit, and thecooking circuit is connected to a power supply. Further, a cookingcontainer for induction heating, such as a pot, is provided, instead ofthe receiver coil 2 of FIG. 1. The pot is provided close to thetransmitter coils so as to be electromagnetically coupled to thetransmitter coils. When a current flows through the transmitter coilsdue to the electromagnetic coupling between the transmitter coils andthe pot, the current generates an electromagnetic field around thetransmitter coils, the electromagnetic field induces electromotive forceon the bottom of the pot, and then, an induced eddy current flows on thebottom of the pot. Since the eddy current can be considered equivalentto a lossy coil, it is possible to define the self-inductance of thepot, and the mutual inductance between the transmitter coils and thepot. According to such an induction heating apparatus, it is possible tostably heat the pot with sufficiently high transmission efficiency, witha very simple configuration, even when a position displacement occursbetween the transmitter coils and the pot.

Although the second to ninth embodiments have been described withreference to the transmitter contactless connector apparatus, theirconfigurations can also be applied to a receiver contactless connectorapparatus (FIG. 12).

In addition, the transmitter coils and the receiver coils are notlimited to be circular shaped, and may be shaped in any shape such asrectangles and ovals.

In addition, the number of turns of the outer transmitter coil and thenumber of turns of the inner transmitter coil are not limited tointegral numbers, and may be fractional numbers or decimal numbers.

In addition, the outer transmitter coil and the inner transmitter coilmay partially overlap each other. In addition, the outer transmittercoil and the inner transmitter coil may be on different planes as shownin FIGS. 21 and 22, etc., as long as they are substantially on the sameplane. In addition, each of the outer transmitter coil and the innertransmitter coil is not limited to be wound in a single layer, and maybe wound in multiple layers.

In addition, FIG. 1, etc. show that the transmitter coils and thereceiver coil are arranged to be parallel to each other. However, thearrangement is not limited thereto, and any other arrangement (e.g., anarrangement where the receiver coil is tilted with respect to thetransmitter coils, etc.) may be used as long as the transmitter coilsand the receiver coil can be electromagnetically coupled to each other.

In addition, FIG. 1, etc. show that each of the transmitter coils andthe receiver coil is wound on a plane. However, the manner of windingthe coils is not limited thereto, and the transmitter coils and thereceiver coil may be wound in any other form, such as a solenoid, aslong as the transmitter coils and the receiver coil areelectromagnetically coupled to each other.

The windings of the outer transmitter coil and the inner transmittercoil are not limited to a single wire, and it is possible to use a Litzwire (for reducing resistance), a conductive pattern of a printedcircuit board (for reducing thickness), a ribbon wire (for reducingresistance), twisted pair wire (for reducing resistance), etc. Thematerial of the windings is not limited to copper wire, and it ispossible to use a multilayered winding, such as copper-clad aluminumwire (for reducing weight) and magnetic-coated copper wire (for reducingloss).

The configurations exemplified above may be combined together.

Base on theoretical calculations, we will describe below the effectsbrought about by the contactless connector systems according to thedescribed embodiments of the present disclosure.

First Implementation Example

FIG. 37 is a perspective view showing a model of transmitter coils andreceiver coils of a contactless connector system according to a firstimplementation example. When each of the transmitter coils 1 a and 1 bof FIG. 1 is wound with one turn, the receiver coil 2 of FIG. 1 is woundwith two turns, and the transmitter coils 1 a, 1 b and the receiver coil2 are sufficiently small compared to the wavelength (when the entirelength of the winding is about 1/10 of the wavelength, e.g., 1/100), thecoils can be approximately replaced by double loops as shown in FIG. 37.It is considered that transmitter coils include an outer transmittercoil 41 a and an inner transmitter coil 41 b, and receiver coils includean outer receiver coil 42 a and an inner receiver coil 42 b. In thefirst implementation example, currents flow through the outertransmitter coil 41 a and the inner transmitter coil 41 b in oppositedirections to each other. In addition, as a first comparison example,the case is also considered in which currents flow through the outertransmitter coil 41 a and the inner transmitter coil 41 b in the samedirection. In both the first implementation example and the firstcomparison example, currents flow through the outer receiver coil 42 aand the inner receiver coil 42 b in the same direction.

We calculated changes in mutual inductance for the case in which theinner transmitter coil 41 b and the inner receiver coil 42 b had theradius D1=16 mm, the outer transmitter coil 41 a and the outer receivercoil 42 a had the radius D3=8 mm, the transmitter coils and the receivercoils were separated by the distance dz=2 mm, and the positiondisplacement dx defined in a manner similar to that in FIG. 3 waschanged from 0 to 20 mm. The mutual inductance M between the transmittercoils and the receiver coils of the contactless connector system of FIG.37 can be decomposed into four components, i.e., M=M11+M12+M21+M22.“M11” denotes the mutual inductance between the inner transmitter coil41 b and the inner receiver coil 42 b, “M12” denotes the mutualinductance between the outer transmitter coil 41 a and the innerreceiver coil 42 b, “M21” denotes the mutual inductance between theinner transmitter coil 41 b and the outer receiver coil 42 a, and “M22”denotes the mutual inductance between the outer transmitter coil 41 aand the outer receiver coil 42 a.

FIG. 38 is a graph showing the mutual inductances between the coils ofthe contactless connector system according to the first comparisonexample. It can be seen that as the position displacement dx increases,the mutual inductances M22 and M11 decrease. However, since the mutualinductance M11 becomes negative when the position displacement dxincreases to about 15 mm, it is expected from the definition that themutual inductance M11 causes the overall mutual inductance M todecrease.

FIG. 39 is a graph showing the mutual inductances between the coils ofthe contactless connector system according to the first implementationexample. It can be seen that as a result of currents flowing through theouter transmitter coil 41 a and the inner transmitter coil 41 b inopposite directions to each other, the signs of the mutual inductancesM11 and M21 are reversed from the case of FIG. 38, and the mutualinductance M11 becomes positive at the position displacement dx=15 mm.

FIG. 40 is a graph showing the sums of the mutual inductances shown inFIGS. 38 and 39. It can be seen that the amount of change in mutualinductance of the contactless connector system of the firstimplementation example is small compared to that of the contactlessconnector system of the first comparison example. Thus, it has beenfound that according to the contactless connector system of the firstimplementation example, there is an effect of preventing changes intransmission efficiency even when a position displacement occurs betweenthe transmitter coils and the receiver coils.

Second Implementation Example

FIG. 41 is a cross-sectional view showing a schematic configuration of acontactless connector system according to a second implementationexample. Litz wire including a bundle of 100 strands with a diameter of0.08 mm was used as transmitter coils. The transmitter coils wereconfigured as an outer transmitter coil 1 a and an inner transmittercoil 1 b wound in opposite directions to each other, the outertransmitter coil 1 a and the inner transmitter coil 1 b including aspiral coil of Litz wire with 20 turns in two layers, and formed bytemporarily picking up the inner 6 turns of the spiral coil, flippingit, and returning it to its original position. The outer diameter of theouter transmitter coil 1 a was 39 mm. The transmitter coils 1 a and 1 bhad the overall self-inductance of 9.6 μH, and the resistance of 69 mΩ.In the case where a magnetic substrate 13 having a relative permeabilityof 2400 was loaded, the transmitter coils 1 a and 1 b had the overallself-inductance of 13.6 μH, and the resistance of 123 mΩ. Whenconsidered using the equivalent circuit of FIG. 4, the internalimpedance Z01 was 1Ω and the capacitance of the capacitor C1 was 270 pF.In addition, receiver coils A and B having the following two sets ofsizes and equivalent circuit parameters (FIG. 4) were used as a receivercoil 2.

(Receiver Coil A)

Outer diameter: 32 mmNumber of turns: 18

C2: 82 nF

dz1: 1.0 mm

Z02: 8.7 Ω (Receiver Coil B)

Outer diameter: 30 mmNumber of turns: 30

C2: 56 nF

dz1: 2.0 mm

Z02: 10.0 Ω

In addition, a spiral coil of Litz wire with 20 turns in the samedirection (i.e., the case of not flipping the winding of an innertransmitter coil 1 b) was also configured as transmitter coils of asecond comparison example. In this case, when considered using theequivalent circuit of FIG. 4, the internal impedance Z01 was 1Ω, and thecapacitance of the capacitor C1 was 120 pF.

FIG. 42 is a graph showing the mutual inductances of the contactlessconnector systems according to the second implementation example and thesecond comparison example. It can be seen that according to the secondimplementation example, since the transmitter coils 1 a and 1 b isconfigured such that, when a current flows through the transmittercoils, the direction of a loop current generated around an axis passingthrough the center by the current flowing through the inner transmittercoil 1 b is opposite to the direction of a loop current generated aroundthe axis by the current flowing through the outer transmitter coil 1 a,it is possible to prevent changes in mutual inductance even when aposition displacement occurs between the transmitter coils and thereceiver coil.

FIG. 43 is a graph showing the transmission efficiency of thecontactless connector system according to the second comparison example.FIG. 44 is a graph showing the transmission efficiency of thecontactless connector system according to the second implementationexample. When the range having the transmission efficiency of 80% ormore is defined as a coverage area, up to the position displacementdx=11 mm can be used in the second comparison example, and up to theposition displacement dx=15 mm can be used in the second implementationexample. Thus, the coverage area can be expanded by a factor of 1.4.

Third Implementation Example

FIG. 45 is a cross-sectional view showing a schematic configuration of acontactless connector system of a third implementation example. Wecalculated changes in transmission efficiency with respect to a positiondisplacement, for the case where transmitter coils had a fixed totalnumber of turns N=15, and the number of turns of an outer transmittercoil 1 a and the number of turns of an inner transmitter coil 1 b werechanged. We used the transmitter coils having an outer diameter of 70mm, an inner diameter of 40 mm, 15 turns, and a copper wire diameter of1.0 mm, and used a receiver coil having an outer diameter of 30 mm, aninner diameter of 10 mm, and 30 turns. In addition, magnetic substrates13 and 16 had the thickness of 0.5 mm, and the relative permeability of2400.

FIG. 46 is a graph showing changes in mutual inductance with respect toa position displacement dx, and with respect to the number of turns ofinner coils, of the contactless connector system of FIG. 45. Thehorizontal axis represents the position displacement dx of the receivercoil, and the vertical axis represents the number of turns of the innertransmitter coils. For each of these conditions, the ratio of the mutualinductance to the peak value [%] (i.e., normalized mutual inductance) isrepresented by contour lines. According to the simulation results, itcan be seen that when the inner transmitter coils has zero turn, themutual inductance becomes 80% of the peak value at the position of theposition displacement dx=20 mm. On the other hand, it can be seen thatwhen the inner transmitter coils has four turns, the distance at whichthe mutual inductance becomes 80% of the peak value is extended to theposition displacement dx=25 mm. It has been found from the simulationresults that in this calculation conditions, it is possible to improvetolerance to a position displacement when the ratio of the number ofturns of the inner transmitter coils to the total number of turns N=15is ⅓ or less.

Fourth Implementation Example

FIG. 47 is a graph showing normalized power transmittable areas ofcontactless connector systems according to a fourth implementationexample and a third comparison example. In the fourth implementationexample, we used transmitter coils having an inner diameter of 12 mm, anouter diameter of 40 mm, and 15 turns, and used a receiver coil havingan inner diameter of 10 mm, an outer diameter of 30 mm, and 11 turns.The distance dz between the transmitter coils and the receiver coil was5 mm. The transmitter coils of the fourth implementation example wereconfigured such that the transmitter coils included an outer transmittercoil and an inner transmitter coil, and currents flowed through theouter transmitter coil and the inner transmitter coil in the oppositedirections to each other. In this case, the numbers of turns of theouter transmitter coil and the inner transmitter coil were configured tochange the ratio of the self-inductance of the inner transmitter coil“Lin” to the self-inductance of the outer transmitter coil “Lout”(Lin/Lout). In the third comparison example, we used transmitter coilsand a receiver coil that have the same dimensions as those in the fourthimplementation example. However, the transmitter coils of the thirdcomparison example were configured such that a current flowed through anouter transmitter coil and an inner transmitter coil in the samedirection in a manner similar to that in FIG. 6.

The simulation results of FIG. 47 were obtained as follows. When thetransmitter coils having a predetermined self-inductance ratio Lin/Loutare configured, the range of displacement, where the change in mutualinductance within ±20% occurs when displacing the receiver coil withrespect to the transmitter coils in the X-direction, is defined as a“power transmittable area” capable of stable power transmission. Thevertical axis in FIG. 47 represents the power transmittable areanormalized by the radius of the transmitter coils. According to thethird comparison example, even when the transmitter coil is split intothe outer transmitter coil and the inner transmitter coil, their mutualinductances do not change, and thus, the power transmittable area isconstant regardless of the self-inductance ratio Lin/Lout. On the otherhand, according to the fourth implementation example, it can be seenthat as the self-inductance of the inner transmitter coil (the number ofreverse turns) increases, the power transmittable area is expanded.However, it can be seen that when the self-inductance ratio Lin/Loutbecomes 0.45 or more, the power transmittable area of the fourthimplementation example falls below that of the third comparison example.This is because the magnetic flux at the center is cancelled out by theouter transmitter coil and the inner transmitter coil.

FIG. 48 is a graph showing an expansion ratio of the power transmittableareas of the contactless connector systems according to the fourthimplementation example and the third comparison example. FIG. 48 showsthe ratio of the power transmittable area of the fourth implementationexample to the power transmittable area of the third comparison example.According to FIG. 48, it can be seen that the expansion ratio becomestwo or more, i.e., its maximum value, near the self-inductance ratioLin/Lout of 0.3. However, it can be seen that when the self-inductanceratio Lin/Lout is 0.45 or more, the expansion ratio of the powertransmittable area becomes one or less, and thus the power transmittablearea becomes narrower than that of the third comparison example.Therefore, it is possible to maximize the power transmittable area byoptimizing the self-inductance ratio between the inner transmitter coiland the outer transmitter coil.

According to FIGS. 47 and 48, it is possible to bring about the effectof expanding the power transmittable area by setting the self-inductanceratio Lin/Lout to less than 0.45. In addition, the best effect isobtained when setting the self-inductance ratio Lin/Lout to 0.3.

Summary of Embodiments

A contactless connector apparatus, a contactless connector system, apower transmission apparatus, and a power transmission system accordingto the aspects of the present disclosure are configured as follows.

According to a contactless connecter apparatus as the first aspect ofthe present disclosure, a contactless connector apparatus is providedwith a first coil closely opposed to a second coil so as to beelectromagnetically coupled to the second coil. The first coil includes:an inner coil wound around an axis passing through a center of the firstcoil; and an outer coil wound around the axis and outside the innercoil. One end of the outer coil and one end of the inner coil areconnected to each other such that, when a current flows through thefirst coil, a direction of a loop current generated around the axis by acurrent flowing through the inner coil is opposite to a direction of aloop current generated around the axis by a current flowing through theouter coil. A self-inductance of the outer coil is larger than aself-inductance of the inner coil.

According to a contactless connecter apparatus as the second aspect, inthe contactless connecter apparatus of the first aspect, a ratio of theself-inductance of the inner coil to the self-inductance of the outercoil is greater than 0 and less than 0.45.

According to a contactless connecter apparatus as the third aspect, inthe contactless connecter apparatus of the first or second aspect, adirection in which the inner coil is wound around the axis is oppositeto a direction in which the outer coil is wound around the axis.

According to a contactless connecter apparatus as the fourth aspect, inthe contactless connecter apparatus of the first or second aspect, adirection in which the inner coil is wound around the axis is same as toa direction in which the outer coil is wound around the axis.

According to a contactless connecter apparatus as the fifth aspect, thecontactless connecter apparatus of one of the first to fourth aspects isfurther provided with a magnetic substrate provided on one side withrespect to the first coil, the one side being opposite to a side wherethe second coil is provided close to the first coil.

According to a contactless connecter apparatus as the sixth aspect, thecontactless connecter apparatus of the fifth aspect is further providedwith a conducting wire connected to the first coil. The magneticsubstrate has a groove into which at least a part of the first coil andthe conducting wire is inserted.

According to a contactless connecter apparatus as the seventh aspect, inthe contactless connecter apparatus of one of the first to sixthaspects, the first coil has a first end close to the axis and a secondend remote from the axis. The contactless connector apparatus furthercomprises a conducting wire connected to the first end, and theconducting wire is wound around the axis so as to gradually increase adistance from the axis.

According to a contactless connecter apparatus as the eighth aspect, inthe contactless connecter apparatus of one of the first to seventhaspects, each of the outer coil and the inner coil is formed on at leastone surface of a printed circuit board using a circuit patterningmethod.

According to a contactless connecter apparatus as the ninth aspect, inthe contactless connecter apparatus of one of the first to eighthaspects, one end of the outer coil and one end of the inner coil areconnected to each other through an impedance element, and the impedanceelement is one of a resistor, a capacitor, an inductor, and a currentinverter circuit.

According to a contactless connecter apparatus as the tenth aspect, thecontactless connecter apparatus of one of the first to ninth aspectsincludes a plurality of first coils wound around a plurality of parallelaxes located at regular intervals, respectively.

According to a contactless connecter system as the eleventh aspect, thecontactless connecter system includes: a contactless connector apparatusof one of the first to tenth aspects, serving as a transmittercontactless connector apparatus; and a receiver contactless connectorapparatus comprising a second coil.

According to a contactless connecter system as the twelfth aspect, thecontactless connecter system includes: a transmitter contactlessconnector apparatus comprising a second coil; and a contactlessconnector apparatus of one of the first to tenth aspects, serving as areceiver contactless connector apparatus.

According to a contactless connecter system as the thirteenth aspect,the contactless connecter system includes: a contactless connectorapparatus of one of the first to tenth aspects, serving as a transmittercontactless connector apparatus; and a contactless connector apparatusof one of the first to tenth aspects, serving as a receiver contactlessconnector apparatus.

According to a power transmission apparatus as the fourteenth aspect,the power transmission apparatus is provided with: a power transmittercircuit; and a contactless connector apparatus of one of the first totenth aspects, the contactless connector apparatus connected to thepower transmitter circuit.

According to a power transmission apparatus as the fifteenth aspect, thepower transmission apparatus is provided with: a power receiver circuit;and a contactless connector apparatus of one of the first to tenthaspects, the contactless connector apparatus connected to the powerreceiver circuit.

According to a power transmission system as the sixteenth aspect, thepower transmission system includes: a contactless connector system ofone of the eleventh to thirteenth aspects; a power transmitter circuitconnected to the transmitter contactless connector apparatus; and apower receiver circuit connected to the receiver contactless connectorapparatus.

According to a contactless connector apparatus as the seventeenthaspect, the contactless connector apparatus is provided with a firstcoil closely opposed to a second coil so as to be electromagneticallycoupled to the second coil. The first coil includes: an inner coil woundaround an axis passing through a center of the first coil; and an outercoil wound around the axis and outside the inner coil. One end of theouter coil and one end of the inner coil are connected to each othersuch that, when a current flows through the first coil, a direction of aloop current generated around the axis by a current flowing through theinner coil is opposite to a direction of a loop current generated aroundthe axis by a current flowing through the outer coil. The inner coil andthe outer coil are configured such that a self-inductance of the outercoil is larger than a self-inductance of the inner coil. The inner coiland the outer coil are configured such that a mutual inductance betweenthe inner coil and the second coil increases as a displacement of thesecond coil to the first coil increases, the displacement indicating adistance between the center of the first coil and a center of the secondcoil. The inner coil and the outer coil are configured such that amutual inductance between the outer coil and the second coil decreasesas the displacement of the second coil increases. The inner coil and theouter coil are configured such that when the center of the first coiland the center of the second coil are close to each other, a negativemutual inductance occurs between the inner coil and the second coil, apositive mutual inductance occurs between the outer coil and the secondcoil, and an absolute value of the mutual inductance between the outercoil and the second coil is larger than an absolute value of the mutualinductance between the inner coil and the second coil. The inner coiland the outer coil are configured such that the displacement of thesecond coil obtained when the mutual inductance between the outer coiland the second coil is zero is larger than the displacement of thesecond coil obtained when the mutual inductance between the inner coiland the second coil is zero.

According to a contactless connector system as the eighteenth aspect,the contactless connector system is provided with: a transmittercontactless connector apparatus provided with a first coil closelyopposed to a second coil so as to be electromagnetically coupled to thesecond coil; and a receiver contactless connector apparatus providedwith the second coil. The first coil includes: an inner coil woundaround an axis passing through a center of the first coil; and an outercoil wound around the axis and outside the inner coil. One end of theouter coil and one end of the inner coil are connected to each othersuch that, when a current flows through the first coil, a direction of aloop current generated around the axis by a current flowing through theinner coil is opposite to a direction of a loop current generated aroundthe axis by a current flowing through the outer coil. The inner coil andthe outer coil are configured such that a self-inductance of the outercoil is larger than a self-inductance of the inner coil. The inner coiland the outer coil are configured such that a mutual inductance betweenthe inner coil and the second coil increases as a displacement of thesecond coil to the first coil increases, the displacement indicating adistance between the center of the first coil and a center of the secondcoil. The inner coil and the outer coil are configured such that amutual inductance between the outer coil and the second coil decreasesas the displacement of the second coil increases. The inner coil and theouter coil are configured such that when the center of the first coiland the center of the second coil are close to each other, a negativemutual inductance occurs between the inner coil and the second coil, apositive mutual inductance occurs between the outer coil and the secondcoil, and an absolute value of the mutual inductance between the outercoil and the second coil is larger than an absolute value of the mutualinductance between the inner coil and the second coil, the displacementof the second coil obtained when the mutual inductance between the outercoil and the second coil is zero is larger than the displacement of thesecond coil obtained when the mutual inductance between the inner coiland the second coil is zero.

According to a contactless connector system as the nineteenth aspect,the contactless connector system is provided with a receiver contactlessconnector apparatus provided with a first coil closely opposed to asecond coil so as to be electromagnetically coupled to the second coil;and a transmitter contactless connector apparatus provided with thesecond coil. The first coil includes: an inner coil wound around an axispassing through a center of the first coil; and an outer coil woundaround the axis and outside the inner coil. One end of the outer coiland one end of the inner coil are connected to each other such that,when a current flows through the first coil, a direction of a loopcurrent generated around the axis by a current flowing through the innercoil is opposite to a direction of a loop current generated around theaxis by a current flowing through the outer coil. The inner coil and theouter coil are configured such that a self-inductance of the outer coilis larger than a self-inductance of the inner coil. The inner coil andthe outer coil are configured such that a mutual inductance between theinner coil and the second coil increases as a displacement of the secondcoil to the first coil increases, the displacement indicating a distancebetween the center of the first coil and a center of the second coil.The inner coil and the outer coil are configured such that a mutualinductance between the outer coil and the second coil decreases as thedisplacement of the second coil increases. The inner coil and the outercoil are configured such that when the center of the first coil and thecenter of the second coil are close to each other, a negative mutualinductance occurs between the inner coil and the second coil, a positivemutual inductance occurs between the outer coil and the second coil, andan absolute value of the mutual inductance between the outer coil andthe second coil is larger than an absolute value of the mutualinductance between the inner coil and the second coil. The inner coiland the outer coil are configured such that the displacement of thesecond coil obtained when the mutual inductance between the outer coiland the second coil is zero is larger than the displacement of thesecond coil obtained when the mutual inductance between the inner coiland the second coil is zero.

According to a contactless connector system as the twentieth aspect, thecontactless connector system is provided with: a transmitter contactlessconnector apparatus provided with a transmitter coil closely opposed toa receiver coil so as to be electromagnetically coupled to a receivercoil; and a receiver contactless connector apparatus provided with thereceiver coil. The transmitter coil includes: an inner transmitter coilwound around a first axis passing through a center of the transmittercoil; and an outer transmitter coil wound around the first axis andoutside the inner transmitter coil. One end of the outer transmittercoil and one end of the inner transmitter coil are connected to eachother such that, when a current flows through the transmitter coil, adirection of a loop current generated around the first axis by a currentflowing through the inner transmitter coil is opposite to a direction ofa loop current generated around the first axis by a current flowingthrough the outer transmitter coil. The inner transmitter coil and theouter transmitter coil are configured such that a self-inductance of theouter transmitter coil is larger than a self-inductance of the innertransmitter coil. The inner transmitter coil and the outer transmittercoil are configured such that a mutual inductance between the innertransmitter coil and the receiver coil in creases as a displacement ofthe receiver coil to the transmitter coil increases, the displacementindicating a distance between the center of the transmitter coil and acenter of the receiver coil. The inner transmitter coil and the outertransmitter coil are configured such that a mutual inductance betweenthe outer transmitter coil and the receiver coil decreases as thedisplacement of the receiver coil increases. The inner transmitter coiland the outer transmitter coil are configured such that when the centerof the transmitter coil and the center of the receiver coil are close toeach other, a negative mutual inductance occurs between the innertransmitter coil and the receiver coil, a positive mutual inductanceoccurs between the outer transmitter coil and the receiver coil, and anabsolute value of the mutual inductance between the outer transmittercoil and the receiver coil is larger than an absolute value of themutual inductance between the inner transmitter coil and the receivercoil. The inner transmitter coil and the outer transmitter coil areconfigured such that the displacement of the receiver coil obtained whenthe mutual inductance between the outer transmitter coil and thereceiver coil is zero is larger than the displacement of the receivercoil obtained when the mutual inductance between the inner transmittercoil and the receiver coil is zero. The receiver coil includes: an innerreceiver coil wound around a second axis passing through the center ofthe receiver coil; and an outer receiver coil wound around the secondaxis and outside the inner receiver coil. One end of the outer receivercoil and one end of the inner receiver coil are connected to each othersuch that, when a current flows through the receiver coil, a directionof a loop current generated around the second axis by a current flowingthrough the inner receiver coil is opposite to a direction of a loopcurrent generated around the second axis by a current flowing throughthe outer receiver coil. The inner receiver coil and the outer receivercoil are configured such that a self-inductance of the outer receivercoil is larger than a self-inductance of the inner receiver coil. Theinner receiver coil and the out er receiver coil are configured suchthat a mutual inductance between the inner receiver coil and thetransmitter coil increases as a displacement of the transmitter coil tothe receiver coil increases, the displacement indicating a distancebetween the center of the receiver coil and the center of the transmitter coil. The inner receiver coil and the outer receiver coil areconfigured such that a mutual inductance between the outer receiver coiland the transmitter coil decreases as the displacement of thetransmitter coil increases. The inner receiver coil and the outerreceiver coil are configured such that when the center of the receivercoil and the center of the transmitter coil are close to each other, anegative mutual inductance occurs between the inner receiver coil andthe transmitter coil, a positive mutual inductance occurs between theouter receiver coil and the transmitter coil, and an absolute value ofthe mutual inductance between the outer receiver coil and thetransmitter coil is larger than an absolute value of the mutualinductance between the inn er receiver coil and the transmitter coil.The inner receiver coil and the outer receiver coil are configured suchthat the displacement of the transmitter coil obtained when the mutualinductance between the outer receiver coil and the transmitter coil iszero is larger than the displacement of the transmitter coil obtainedwhen the mutual inductance between the inner receiver coil and thetransmitter coil is zero.

According to a power transmission apparatus as the twenty-first aspect,the power transmission apparatus is provided with: a power transmittercircuit; and a contactless connector apparatus connected to the powertransmitter circuit. The contactless connector apparatus is providedwith a first coil closely opposed to a second coil so as to beelectromagnetically coupled to the second coil. The first coil includes:an inner coil wound around an axis passing through a center of the firstcoil; and an outer coil wound around the axis and outside the innercoil. One end of the outer coil and one end of the inner coil areconnected to each other such that, when a current flows through thefirst coil, a direction of a loop current generated around the axis by acurrent flowing through the inner coil is opposite to a direction of aloop current generated around the axis by a current flowing through theouter coil, the inner coil and the outer coil are configured such thatthe inner coil and the outer coil are configured such that aself-inductance of the outer coil is larger than a self-inductance ofthe inner coil. The inner coil and the outer coil are configured suchthat a mutual inductance between the inn er coil and the second coilincreases as a displacement of the second coil to the first coilincreases, the displacement indicating a distance between the center ofthe first coil and a center of the second coil. The inner coil and theouter coil are configured such that a mutual inductance between the outer coil and the second coil decreases as the displacement of the secondcoil increases. The inner coil and the outer coil are configured suchthat when the center of the first coil and the center of the second coilare close to each other, a negative mutual inductance occurs between theinner coil and the second coil, a positive mutual inductance occursbetween the outer coil and the second coil, and an absolute value of themutual inductance between the outer coil and the second coil is largerthan an absolute value of the mutual inductance between the inner coiland the second coil. The inner coil and the outer coil are configuredsuch that the displacement of the second coil obtained when the mutualinductance between the outer coil and the second coil is zero is largerthan the displacement of the second coil obtained when the mutualinductance between the inner coil and the second coil is zero.

According to a power transmission apparatus as the twenty-second aspect,the power transmission apparatus is provided with: a power receivercircuit; and a contactless connector apparatus connected to the powerreceiver circuit. The contactless connector apparatus is provided with afirst coil closely opposed to a second coil so as to beelectromagnetically coupled to the second coil. The first coil includes:an inner coil wound around an axis passing through a center of the firstcoil; and an outer coil wound around the axis and outside the innercoil. One end of the outer coil and one end of the inner coil areconnected to each other such that, when a current flows through thefirst coil, a direction of a loop current generated around the axis by acurrent flowing through the inner coil is opposite to a direction of aloop current generated around the axis by a current flowing through theouter coil. The inner coil and the outer coil are configured such that aself-inductance of the outer coil is larger than a self-inductance ofthe inner coil. The inner coil and the outer coil are configured suchthat a mutual inductance between the inner coil and the second coilincreases as a displacement of the second coil to the first coilincreases, the displacement indicating a distance between the center ofthe first coil and a center of the second coil. The inner coil and theouter coil are configured such that a mutual inductance between theouter coil and the second coil decreases as the displacement of thesecond coil increases. The inner coil and the outer coil are configuredsuch that when the center of the first coil and the center of the secondcoil are close to each other, a negative mutual inductance occursbetween the inner coil and the second coil, a positive mutual inductanceoccurs between the outer coil and the second coil, and an absolute valueof the mutual inductance between the outer coil and the second coil islarger than an absolute value of the mutual inductance between the innercoil and the second coil. The inner coil and the outer coil areconfigured such that the displacement of the second coil obtained whenthe mutual inductance between the outer coil and the second coil is zerois larger than the displacement of the second coil obtained when themutual inductance between the inner coil and the second coil is zero.

According to a power transmission system as the twenty-third aspect, thepower transmission system is provided with: a contactless connectorsystem provided with a transmitter contactless connector apparatus and areceiver contactless connector apparatus; a power transmitter circuitconnected to the transmitter contactless connector apparatus; and apower receiver circuit connected to the receiver contactless connectorapparatus. The transmitter contactless connector apparatus is providedwith a transmitter coil closely opposed to a receiver coil so as to beelectromagnetically coupled to a receiver coil. The a receivercontactless connector apparatus is provided with the receiver coil. Thetransmitter coil includes: an inner transmitter coil wound around afirst axis passing through a center of the transmitter coil; and anouter transmitter coil wound around the first axis and outside the innertransmitter coil. One end of the outer transmitter coil and one end ofthe inner transmitter coil are connected to each other such that, when acurrent flows through the transmitter coil, a direction of a loopcurrent generated around the first axis by a current flowing through theinner transmitter coil is opposite to a direction of a loop currentgenerated around the first axis by a current flowing through the outertransmitter coil. The inner transmitter coil and the outer transmittercoil are configured such that a self-inductance of the outer transmittercoil is larger than a self-inductance of the inner transmitter coil. Theinner transmitter coil and the outer transmitter coil are configuredsuch that a mutual inductance between the inner transmitter coil and thereceiver coil increases as a displacement of the receiver coil to thetransmitter coil increases, the displacement indicating a distancebetween the center of the transmitter coil and a center of the receivercoil. The inner transmitter coil and the outer transmitter coil areconfigured such that a mutual inductance between the outer transmittercoil and the receiver coil decreases as the displacement of the receivercoil increases. The inner transmitter coil and the outer transmittercoil are configured such that when the center of the transmitter coiland the center of the receiver coil are close to each other, a negativemutual inductance occurs between the inner transmitter coil and thereceiver coil, a positive mutual inductance occurs between the outertransmitter coil and the receiver coil, and an absolute value of themutual inductance between the outer transmitter coil and the receivercoil is larger than an absolute value of the mutual inductance betweenthe inner transmitter coil and the receiver coil. The inner transmittercoil and the outer transmitter coil are configured such that thedisplacement of the receiver coil obtained when the mutual inductancebetween the outer transmitter coil and the receiver coil is zero islarger than the displacement of the receiver coil obtained when themutual inductance between the inner transmitter coil and the receivercoil is zero. The receiver coil includes: an inner receiver coil woundaround a second axis passing through the center of the receiver coil;and an outer receiver coil wound around the second axis and outside theinner receiver coil. One end of the outer receiver coil and one end ofthe inner receiver coil are connected to each other such that, when acurrent flows through the receiver coil, a direction of a loop currentgenerated around the second axis by a current flowing through the innerreceiver coil is opposite to a direction of a loop current generatedaround the second axis by a current flowing through the outer receivercoil. The inner receiver coil and the outer receiver coil are configuredsuch that a self-inductance of the outer receiver coil is larger than aself-inductance of the inner receiver coil. The inner receiver coil andthe outer receiver coil are configured such that a mutual inductancebetween the inner receiver coil and the transmitter coil increases as adisplacement of the transmitter coil to the receiver coil increases, thedisplacement indicating a distance between the center of the receivercoil and the center of the transmitter coil. The inner receiver coil andthe outer receiver coil are configured such that a mutual inductancebetween the outer receiver coil and the transmitter coil decreases asthe displacement of the transmitter coil increases. The inner receivercoil and the outer receiver coil are configured such that when thecenter of the receiver coil and the center of the transmitter coil areclose to each other, a negative mutual inductance occurs between theinner receiver coil and the transmitter coil, a positive mutualinductance occurs between the outer receiver coil and the transmittercoil, and an absolute value of the mutual inductance between the outerreceiver coil and the transmitter coil is larger than an absolute valueof the mutual inductance between the inner receiver coil and thetransmitter coil. The inner receiver coil and the outer receiver coilare configured such that the displacement of the transmitter coilobtained when the mutual inductance between the outer receiver coil andthe transmitter coil is zero is larger than the displacement of thetransmitter coil obtained when the mutual inductance between the innerreceiver coil and the transmitter coil is zero.

INDUSTRIAL APPLICABILITY

According to a contactless connector apparatus, a contactless connectorsystem, a power transmission apparatus, and a power transmission systemof the present disclosure, it is possible to achieve stable powertransmission with sufficiently high transmission efficiency, with a verysimple configuration, even when a position displacement occurs between atransmitter coil and a receiver coil.

In addition, it is conventionally necessary to increase transmissionpower in order to deal with a reduction in transmission efficiency, thusresulting in increased heat generation. On the other hand, thetransmission efficiency does not decrease in the contactless connectorapparatus, the contactless connector system, the power transmissionapparatus, and the power transmission system of the present disclosure,and thus, there is an effect of preventing heat generation.

REFERENCE SIGNS LIST

-   -   1, 1 a, 1 b, 1 aa, 1 ba, 1 ab, 1 bb, 1 ac, 1 bc, 1 c, 1 d, 31-1        to 31-3, 32-1 to 32-3, 41 a, and 41 b: TRANSMITTER COIL,    -   2, 2 a, 2 b, 42 a, and 42 b: RECEIVER COIL,    -   3, 3A to 3D, 4, and 7: CONNECTING ELEMENT,    -   5, 6, and 6A to 6C: CONDUCTING WIRE,    -   11 and 12: HOUSING,    -   13 and 16: MAGNETIC SUBSTRATE,    -   14: DIELECTRIC SUBSTRATE,    -   15, 15A, 15B1 to 15B3, 15C, and 15D: VIA CONDUCTOR,    -   21: IMPEDANCE ELEMENT,    -   101: POWER SUPPLY,    -   102: POWER TRANSMITTER CIRCUIT,    -   103: POWER RECEIVER CIRCUIT,    -   104: LOAD,    -   C1 and C2: CAPACITOR,    -   G1 and G2: GROOVE,    -   L1 and L2: SELF-INDUCTANCE,    -   M: MUTUAL INDUCTANCE,    -   P1 to P14: TERMINAL,    -   R1 and R2: RESISTANCE COMPONENT,    -   Q: SIGNAL SOURCE, and    -   Z01 and Z02: LOAD IMPEDANCE.

1. A power transmission apparatus comprising: a power receiver circuit;and a contactless connector apparatus connected to the power receivercircuit, wherein the contactless connector apparatus comprises a firstcoil closely opposed to a second coil so as to be electromagneticallycoupled to the second coil, wherein the first coil includes: an innercoil wound around an axis passing through a center of the first coil;and an outer coil wound around the axis and outside the inner coil,wherein one end of the outer coil and one end of the inner coil areconnected to each other such that, when a current flows through thefirst coil, a direction of a loop current generated around the axis by acurrent flowing through the inner coil is opposite to a direction of aloop current generated around the axis by a current flowing through theouter coil, and wherein the inner coil and the outer coil are configuredsuch that: a self-inductance of the outer coil is larger than aself-inductance of the inner coil, a mutual inductance between the innercoil and the second coil increases as a displacement of the second coilto the first coil increases, the displacement indicating a distancebetween the center of the first coil and a center of the second coil, amutual inductance between the outer coil and the second coil decreasesas the displacement of the second coil increases, when the center of thefirst coil and the center of the second coil are close to each other, anegative mutual inductance occurs between the inner coil and the secondcoil, a positive mutual inductance occurs between the outer coil and thesecond coil, and an absolute value of the mutual inductance between theouter coil and the second coil is larger than an absolute value of themutual inductance between the inner coil and the second coil, thedisplacement of the second coil obtained when the mutual inductancebetween the outer coil and the second coil is zero is larger than thedisplacement of the second coil obtained when the mutual inductancebetween the inner coil and the second coil is zero.